Method of joining two components, auxiliary joining part and components assembly

ABSTRACT

A method of connecting a first component and a second component with the aid of an auxiliary joining part, wherein the auxiliary joining part is formed from a pin and a plate. A position of intended fracture is present between the plate and the pin. The first component, the second component and the auxiliary joining part are brought into a stacked arrangement such that the plate contacts the first component and the pin projects away from the side of the plate remote from the first component. A force is exerted on the pin of the auxiliary joining part in the direction towards the stacked components which leads to a fracture at a position of intended fracture and the pin is used in order to pierce slugs from the stacked components. The end of the pin which is pressed through the second component, and/or a washer which is optionally provided there, is deformed in order to provide a form-locked connection to the second component or to a washer which is provided there. Furthermore, an auxiliary joining part is claimed.

CROSS REFERENCE TO RELATED APPLICATION

This divisional application claims priority to U.S. application Ser. No.16/044,615, filed Jul. 25, 2018, which is incorporated herein byreference in its entirety.

The present invention relates to a method for the joining of a firstcomponent and a second component with the aid of an auxiliary joiningpart, wherein the auxiliary joining part is formed of a pin and a plateand also to an auxiliary joining part and to a component assemblymanufactured by the method. The components can be sheet metal partsand/or organic sheet parts.

Organic sheet parts are components which as a result of their planar orthree-dimensional shape resemble sheet metal parts and can at least inpart be handled in the same way as these, but which consist of anon-metallic composite material such as a fiber or fabric reinforcedplastic. Such composite materials generally have high strength fiberssuch as, for example, aramid fibers, carbon fibers or glass fibers whichare embedded either as relatively short filling fibers or as longfilaments, or in the form of a fabric manufactured from filaments, intoa matrix material of plastic. Thermoplastic materials can indeed be usedas the plastic for coachwork components; however, duroplastics areusually used. Organic sheet parts are finding increasing use in theconstruction of coachwork and in other fields of technology, as a resultof their characteristics such as light-weight, high mechanical loadcarrying ability and good formability.

One problem in connecting two organic sheet parts, or an organic sheetpart to a sheet metal part, lies in fact that some of the establishedjoining processes, such as for example punch riveting, are not suitablefor fiber or fabric reinforced plastics.

A method of the initially named kind and also a component assemblyformed from the joined components, is already known from DE 10 2014 113438 A1 and/or from the corresponding EP-A-2873473 which is suitable forjoining areal components, in particular when one of the components isformed as an organic sheet part. The areal components can be planarcomponents or have a three-dimensional shape. The known punch rivetingprocess can be used with a plurality of individual components which arelaid on top of one another, with the components being present in theform of at least two metallic sheet metal parts, or of at least twoorganic sheet parts, i.e. plastic components with fiber or fabricreinforcement, or of at least one metallic component and at least oneorganic component.

The need exists to enable a simple and effective joining of sheet partsof which at least one can be an organic sheet part. Furthermore, aneconomical method should be presented which requires only a small numberof individual components and which facilitates the handling of theindividual components.

In accordance with claim 1 a method of joining a first component and asecond component with the aid of an auxiliary joining part is provided,with the auxiliary joining part consisting of a pin and a plate, withthe special characterizing feature that a position of intended fractureis present between the plate and the pin, wherein

(i) the first component, the second component and the auxiliary joiningpart are brought into a stacked arrangement such that the plate contactsthe first component and the pin projects away from the side of the plateremote from the first component,

(ii) a force is exerted on the pin of the auxiliary joining part in thedirection towards the stacked components which leads to a fracture at aposition of intended fracture and the pin is used in order to pierceslugs from the stacked components,

(iii) the end of the pin which is pressed through the second component,and/or a washer which is optionally provided there is deformed in orderto provide a form-locked connection to the second component or to awasher which is provided there and

(iv) the plate and/or the end of the pin which was originally remotefrom the plate, but is now adjacent to it, is deformed in order to alsoproduce a form-fitted connection there.

The auxiliary joining part which is used is characterized in that itconsists of a pin and of a plate provided at the pin, with a position ofintended fracture being present between the plate and the pin.

The auxiliary joining part is thus used in a similar manner to aso-called solid punch rivet. As a result of the auxiliary joining partwhich consists of a pin and a plate and has no loose individualcomponents, it is not only possible to achieve a simple and efficientconnection of the sheet parts. In addition, as a result of theconnection between the plate and the pin of the auxiliary joining part,handling difficulties are avoided because instead of having to operatewith two loose parts which have to be separately handled and held, onlythe auxiliary joining part has to be positioned on the sheet parts. Theentire system thus consists in the ideal case of a first and a secondcomponent, an auxiliary joining part and optionally a washer having ahole, to the extent that the component remote from the plate is not ametallic component which can be directly connected to the adjacent endof the pin.

In accordance with the invention the auxiliary joining part ispositioned on the sheet metal parts in such a way that the platecontacts the first component, which can be a metallic sheet metal partor an organic sheet part and the pin projects away from the side of theplate remote from the first component. Thereafter a force is exerted onthe pin whereby the position of intended fracture is broken and the pinis subsequently used to punch slugs from the stacked components.

The pin is pressed through to such an extent that it passes through thecomponents that are present to the extent that a form-fitted connectioncan be produced with the two ends of the pin as is described in detailin the above-named EP document (EP-A2873473). In this connection aform-fitted connection is made between the one end of the pin which wasoriginally remote from the plate with the plate, while the other end ofthe pin which was originally arranged adjacent the plate is brought intoa form-fitted connection with the component remote from the plate(provided this consists of a metal) or with a washer provided there (incase the component remote from the plate is an organic sheet part). Inthis connection there are basically two possibilities of forming the twoform-fitted connections with the ends of the pin. On the one hand ametallic material of the sheet metal part or a washer can be formed intorespective undercuts of the pin, on the other hand the ends of the pincan be so embossed that the required shape fitted connection with theplate and with the component remote from the plate, or the washerprovided there, arises.

Further developments of the invention can be found in the dependentclaims, in the description and also the accompanying drawings.

In general, the method claimed here applies to areal components whichhave a planar shape or a three-dimensional shape and are present in theform of at least two metallic sheet metal parts or of at least twoorganic sheet parts, i.e. plastic components with a fiber or fabricreinforcement or in the form of at least one metallic component and atleast one organic component.

At least during the step (ii), i.e. the punching through of the stackedarrangement of the components, the first component is clamped to thesecond component and optionally to the washer. This ensures that anyorganic sheet parts can be cleanly punched through by means of the pinwithout the hole edge of any organic sheet part that is present andwhich is produced during the punching being frayed out.

In this way it can be ensured that the punch rivet process can becarried out without problems. Through the fixed preloading or clampingof the first and second component faulty positioning or a slippage ofone of the two plates during the punch rivet process is avoided.Furthermore, a rotationally secure connection is produced between thecomponents because of the frictional connection that is generated.

The position of intended fracture between the plate and the pin thusforms a weakened position which allows the plate and the pin to betransported and handled as a unit, but which however makes it possible,on the operation of a corresponding force, to enable a movement of thepin relative to the plate.

Through the position of intended fracture, it is not only ensured thatthe plate can be separated from the pin but also the local partitionline is preset.

In accordance with a special design, the plate of the auxiliary joiningpart is in particular made circular. Through the circular design thehandling is, on the one hand, facilitated because the auxiliary joiningpart does not have to be aligned around the middle longitudinal axiswith regard to the geometrical form. Also, the ability to manufacturethe plate and the complete auxiliary joining part is simplified throughthe circular design, since the plate can be present as a simple metallicdisc.

A further special design envisages that the pin is in particular ofcylindrical or prismatic shape in cross-section. In this way a simplemanufacture of the auxiliary joining part is made possible. Furthermore,the piercing of the first and second sheet parts is facilitated by acylindrical or prismatic design. With a prismatic design a certainadditional security against rotation can be produced between thecomponents.

As stated the auxiliary joining part which is to be used in accordancewith the invention comprises a pin, a plate and a position of intendedfracture. In this way the auxiliary joining part can be regarded as onecomponent. The auxiliary joining part can be integrally manufactured, ormade in one piece, for example by a cold heading process, or it can bemanufactured from a pin and a plate manufactured separately from thepin. The pin can in this connection be soldered, welded, adhesivelybonded, or joined to the plate by another method, in a shape fittedand/or force transmitting manner.

For the shape fitted connection of one end of the pin to the plate, andto the component remote from the plate, or to the washer, an undercutcan be present at at least one end of the pin. Respective undercuts canalso be provided at both ends of the pin.

In this connection the pin is so positioned that the undercut issurrounded at least partly by disc material or plate material.Furthermore, when using a sheet metal part, the undercut can besurrounded by the sheet metal part. By exerting an adequate pressure onthe metallic disc or the plate of the auxiliary joining part, materialof the disc or the plate is driven into the undercut and the auxiliaryjoining part is thereby joined to the metallic disc or the plate. Astable connection results as a result of the material driven into theundercut. The connection can be considered as a form fitted connectionand a force transmitting connection.

It is however not essential to provide such undercuts since, asdescribed in the above-named EP document (EP-A-2873473) the ends of thepin can be so embossed that the required shape fitted and forcetransmitting connection to the plate and to the component and/or to thewasher remote from the plate arises.

The invention will be described in the following in more detail by wayof example with reference to embodiments and referring to the drawingsin which are shown:

FIG. 1 a plan view of the auxiliary joining part which is used for thejoining of two component in accordance with the invention,

FIG. 2 a side-view of the auxiliary joining part of FIG. 1 ,

FIG. 3 a cross-section through the auxiliary joining part which islikewise shown in FIGS. 1 and 2 ,

FIGS. 4A to 4E various embodiments of the position of intended fractureat auxiliary joining parts,

FIG. 5 a stacked arrangement prior to the carrying out of the punchriveting process with an auxiliary joining part having a plate, a firstcomponent and a second component, with at least the second (lower)component being a sheet metal part,

FIG. 6 the arrangements in accordance with FIG. 4 during the punch rivetprocess,

FIG. 7 the component assembly which arises after the conclusion of thepunch rivet process,

FIG. 8A the auxiliary joining part in accordance with FIGS. 1 to 3 or inaccordance with FIGS. 4A to 4E in an attachment apparatus which servesfor the attachment of the auxiliary joining part to two components, ofwhich at least the lower one is formed by an organic plate and the upperone is either likewise formed by an organic plate or by a sheet metalpart, while using a separate washer which is arranged in theillustration beneath the two components,

FIG. 8B the finished component assembly after the attachment of theauxiliary joining part in the apparatus of FIG. 8A,

FIGS. 9A to 9D various phases of the attachment of an alternativeauxiliary joining part with undercuts at both ends to two componentslying on top of one another which are preferably present as organicsheet metal parts, but which could also be formed by two sheet metalparts or by one sheet metal part and one organic component,

FIG. 10A a component assembly resulting from the attachment process inaccordance with FIGS. 9A to 9D having a disc-like plate, a furtherwasher and with two components located between the plate and the washer,

FIG. 10B an enlarged illustration of the connection of the furtherseparate washer of FIG. 10A with one end of the auxiliary joining part,

FIG. 11 a perspective illustration of the inner punch of a preferredsetting head for the embossing of a pin at the upper end of theauxiliary joining part having undercuts at both ends,

FIG. 12 a perspective illustration of a hold-down member which surroundsand is matched in shape to the inner punch in accordance with FIG. 11 ,

FIGS. 13A to 13D various phases of the attachment process for anauxiliary joining part having undercuts at both ends using the internalpunch and the hold-down member of FIGS. 11 and 12 respectively,

FIGS. 14A and 14B the component assembly in a sectioned drawing (FIG.14A) which results from the attachment process in accordance with FIGS.13A to 13D and in a perspective representation (FIG. 14B) the finishedcomponent assembly in accordance with FIG. 14A seen generally obliquelyfrom above in FIG. 14A,

FIG. 14C a perspective illustration of the finished component assemblyin accordance with FIG. 14A seen in generally obliquely from below inFIG. 14A, and

FIGS. 15A to 15C a further alternative of an auxiliary joining part in aperspective illustration (FIG. 15A) in a detailed drawing (FIG. 15B) ofthe position of intended fracture of the auxiliary joining part of FIG.15A and in FIG. 15C a view of the auxiliary joining part in accordancewith FIG. 15A partly sectioned in the longitudinal direction.

The auxiliary joining part shown in FIGS. 1 to 3 has a plate 13 and apin 15. In addition, a position of intended fracture 17 is clearlyrecognizable above all in FIGS. 1 and 3 . A position of intendedfracture 17 of the plate 13 is in this case formed as a weakenedposition. The position of intended fracture 17 weakens the connection ofthe plate 13 with the pin 15 as a result of the reduced cross-section atthe position of intended fracture and through the notch action producedat the position of intended fracture 17. As a result of the weakenedposition the pin 15 breaks through the plate 13 as soon as acorresponding force K acts in the arrow direction shown on the end face16 of the pin 15. The smaller the cross-section which is loaded in shearis made at the position of intended fracture, the lower is the forcewhich needs to be expended in order to induce the punch rivet process.If the pin 13 has broken through the plate then it is moved by thecontinued action of force in the direction B (FIG. 5 ), i.e. downwardlyin the longitudinal direction L in the drawings.

As can be seen in FIG. 1 the plate 13 is preferably of circular shape.Through the circular shape of the plate 13 the positioning of theauxiliary joining part 11 on the first sheet part 21 is facilitated,i.e. attention only needs to be paid to the correct alignment andpositioning of the pin 15 and the orientation of the auxiliary joiningpart 11 around the central longitudinal axis L does not have any role toplay as a result of the symmetry. The circular plate 13, which in thiscase is present in one piece with the pin, is, on the one hand,relatively easy to manufacture in a cold heading process. It is,however, likewise possible to make the plate in the form of a platehaving corners or edges. During the cold heading process a recess 18(FIG. 3 ) is formed in the region of the plate so that only littlematerial remains in the corner region of the recess 18 whereby theposition of intended fracture 17 is manufactured.

The pin 15 of the auxiliary joining part 11 can furthermore be providedwith an undercut 19. In the present drawings the pin 15 is provided withat least one undercut such as 19 at the end of the pin which liesadjacent to the plate (here it is for example one undercut which isformed by four circular recesses 20). As already mentioned the pin 15can however also have no undercuts 19 or a plurality of undercuts.

The pin 15 is preferably of cylindrical or prismatic shape. In thisembodiment an advantage also results such as simple manufacture fromwire material. Furthermore, a uniform and simple punching process ismade possible with the aid of the pin. In addition, the manufacture issimplified and thus more economical. The formation of the possibleundercuts 19 or circular recesses 20 on the surface of the pin 15 issimplified by prismatic and in particular however by a cylindricaldesign, since the undercut can be provided by the cold heading processbut also by a rolling process.

In general the auxiliary joining part 11 consists, as shown, of a plate13, a pin 15 and a position of intended fracture 17 introduced betweenthem. In addition, the auxiliary joining part can have an undercut. Theplate 13 and the pin 15 can, as shown in the illustrated embodiment beintegrally made, with the position of intended fracture 17 in particularbeing formed as a weakened position with respect to the materialstrength or thickness. It is, however, likewise conceivable that the pin15 is for example soldered, welded or adhesively bonded to the plate 13.The connection of the two components then forms the position of intendedfracture 17. Furthermore, the pin could be fastened to the plate in aforce transmitting or shape matched form, provided the forcetransmitting form or the shape matched form is so designed that thedesired position of intended fracture 17 results. Examples for thistwo-part construction are shown in FIGS. 4A to E. FIG. 4A shows asoldered construction with soldered joint 30. FIG. 4B shows a designwith a brazed joint 31. FIG. 4C shows a design having a few weld joints32. FIG. 4D shows a design with an adhesively bonded connection 34 andFIG. 4E shows a design with a force transmitting and shape matchedconnection 35. FIG. 4E.1 shows a cross-sectional view of the auxiliaryjoining part 11 with a force transmitting and shape matched connection35. FIG. 4E.2 shows a plan view of the auxiliary joining part 11. Bothviews are to be understood as falling under the designation of FIG. 4E.In FIG. 4E a force transmitting and shape matched connection is shownwhich is achieved by an interference fit. In this connection the pin end15 has fine splines and is secured with the aid of the force fit in anopening of the plate 13. A position of intended fracture 17 arises as aresult of the mechanical anchorage. In use the pin 15 can be pressed byan increased use of force through the plate 13. A design of theauxiliary joining part in two parts is, on the one hand, somewhat morecomplicated than an integral manufacture, but nevertheless reasonablebecause simple washer can be used for the plate 13 and metal bars forthe pin 15.

In FIGS. 5 to 7 a method is shown which is used for the insertion of theauxiliary joining part into the components. The auxiliary joining part11, the first component 21, the second component 23 and a die button 25having a ring-shaped projection 28 can be seen. At this point it shouldbe emphasized that the invention is in no way restricted to theconnection of two components to one another, it can be used with morethan two components, with the further components being understood asintermediate components which can optionally consists of organiccomponents or of sheet metal parts.

As shown in FIG. 5 the auxiliary joining part 11 is held in aschematically illustrated setting head 41 which has a spring loaded,cylindrical, hold-down member 43 and a holder 45 for the pin of theauxiliary joining part. The holder 45 can for example have a ring ofpolyurethane 47 which presses against the pin 15 and holds it by theresulting friction within the setting head 41. Above the upper end ofthe pin 15 there is a plunger 49 which can be moved downwardly in orderto press the pin 15 downwardly and to break the position of intendedfracture 17. Such setting heads 41 are well known and are normallyinstalled in a tool 51 of a press while the die button is supported byanother tool 43 of the press. By way of example the setting head 41 canbe mounted at the upper tool 51 of the press, whereas the die button 25is carried by an intermediate platen 53 of the press or by a lowerplaten 55 of the press. The setting head 41 can however also beinstalled at the intermediate platen 53 of a press when the die button25 is mounted at the lower platen 55 of the press. Reverse arrangementsare also possible in which the setting head 41 is mounted at the lowerplaten 55 of the press or at an intermediate platen 53 of the press,whereas the die button 55 is then respectively carried by theintermediate platen 53 of the press or by the upper tool 51 of thepress. Further constructions are also conceivable for example in anautomated supply the setting head 41 can be carried by a robot whichmoves the setting head 41 towards a die button 25.

Furthermore, the setting head 41 and the die button 25 can be installedat the corresponding ends of a force actuated pair of tongs. By way ofexample, a spring 57 can act between the upper plate 51 of a press andthe hold-down member 43 in order, in a first closing phase of the press,to press the plate 13 of the auxiliary joining part 11, the firstcomponent 21 and the second component 23 (and also any furthercomponents) firmly against one another and against the die button 25.During this phase the plunger 49 does not initially press against theupper end of the pin 15 of the auxiliary joining part 11. During afurther closing phase of the press the spring-loaded hold-down member 43still exerts a clamping force on the plate 13 of the auxiliary joiningpart 11, on the first component 21, on the second component 13 and onthe die button 25 but now the upper end of the plunger 49 comes intocontact with the upper tool 51 of the press or with an abutment of thesetting head 41 and drives the pin 15 of the auxiliary joining part 11downwardly, whereby the position of intended fracture 17 is broken andthe end of the pin 15 which was initially adjacent the plate punchesthrough the components and produces slugs 27 which are disposed of viathe bore of the die button 25.

Through the action of force on the pin 15, for example on its upper endface 16 in the direction K, the pin 15 is separated from the plate atthe position of intended fracture 17 and driven through the plate 13.Through the continued action of force the pin is punched through thefirst component 21 and the second component 23 (and also any furthercomponents) with slugs 27 being separated from the components. The pin15 is driven in to such an extent that the slugs 27 fall through thebore of the die button 25 and the pin 15 is positioned, as shown in FIG.7 essentially within the components. The slugs 27 fall into the hollowdie button 25 and are subsequently led away while the second component23 still lies firmly on the die button 25. Through the continued actionof force of the press the lower component is pressed against thering-like projection 28 of the die button whereby the component 23 ispressed in at the lower side and the sheet metal material is driven intothe undercut 19. One notes that the undercut 19 or each ring of theundercut has a slightly conical flank in the press-in direction whichensures that the resisting forces during the punching movement are notexcessively high whereas the following flank in the press-in directionhas a substantially steeper conical shape whereby, after the shaping ofthe sheet metal material of the component 23 into the undercut 19, ahigh press-out resistance is generated. The flank following in thepress-in direction could also stand perpendicular to the centrallongitudinal axis L.

As described in EP-A-2873473, the upper end face 16 of the pin 15 issimultaneously embossed by the plunger 49, which is shown here onlypurely schematically, whereby a form-fitted engagement 29 (FIG. 7 ) withthe plate 13 is generated.

The first component 21 is fixedly riveted to the second component 23.The deformation or embossing 29 of the end face 16 of the pin 15 by thelower end of the plunger 49 of the setting head 41 takes place preciselyas described in EP document EP-A-2873473.

A form-fitted connection with the plate 13 at the upper end of the pin15 could likewise be achieved if the pin 15 also has an undercut 19 atthe upper end as in FIG. 5 , whereby the metallic material of the plate13 is driven into the undercut 19. In this case the lower end face ofthe holder 45 would likewise be provided with a ring-like projectionsimilar to the ring-like projection 28.

In like manner both end faces 16 can be deformed or embossed (as willlater be explained in more detail) whereby a form-fitted connection ofthe auxiliary joining part 11 with the first component 21 and the secondcomponent 23 can be achieved by corresponding deformations or embossing29. For this purpose, the die button 25 can be made in a similar mannerto the plunger 49 in order to generate the embossing in similar mannerto that described in EP-A-2873473.

With respect to the drawings of FIGS. 5 to 7 the simplified handling isabove all evident since the number of individual components is kept assmall as possible and thus a source of possible faults in the punchrivet process is avoided.

It is evident that the components 21 and 23 in this example are arealcomponents at least in the region of the setting head 41, i.e. have aplanar shape at least there. They can however also have athree-dimensional such as, for example, curved coachwork parts of avehicle. The components 21 and 23 can be formed by two metallic sheetmetal parts or by two organic sheet parts, i.e. plastic components withfiber or fabric reinforcement. As an alternative, they can be formed byone organic sheet part and one sheet metal part.

Furthermore, more than two components can be riveted together, with thefurther components optionally being metallic sheet parts and/or organicsheet parts.

In the illustrated embodiment of FIGS. 5 to 7 the first component 21 isformed as an organic sheet part and the second component 23 as a sheetmetal part. That is to say, the first component 21 consists ofnon-metallic composite material with a fiber reinforced or fabricreinforced plastic. The second component 23 consists of a metal, fromthis the advantage arises above all that a metallic material has acorresponding flow property and, under the influence of a force whichoriginates from a plunger 49 and the die button 25, can be driven intothe undercut 19. For this purpose, the die button 25 has a ring-likeprojection 28 around the bore which forms the sheet material into theundercuts 19. This is not the only possibility of generating aform-fitted connection between the lower end of the pin 15 and the sheetmetal part. It is for example also possible, as explained in the EPdocument EP-A-2873473 to emboss the lower end of the pin 15 such thatthe material overlap arises with the component 23, at least atpositions, for example at three positions uniformly spaced around thecentral longitudinal axis L. The first component 21 which is formed asan organic sheet metal part has no corresponding flow properties. Forthis reason, the organic sheet part is always paired with a metal washeror the plate 13 of the auxiliary joining part in order to enable a solidriveted connection. As is evident from FIGS. 5 to 7 the plate 13 of theauxiliary joining part 11 lies on the first component 21, here anorganic sheet metal part. It serves for the uniform distribution of theriveting forces onto the finished component assembly in accordance withFIG. 7 . Should the first component 21 be a metallic sheet part then theprovision of the plate 13 is in no way disadvantageous.

If not only the first component 21 is formed as an organic sheet part,but rather also the second component 23, then a further metal washer(not shown) is required. This is introduced in analogous manner to theplate 13, to the stacked arrangement and is received in a correspondingwasher shaped recess of the die button (likewise not shown but knownfrom EP-A-2873473) beneath the second component 23. The washer-shapeddepression can then have the ring-shaped projection 28 around the boreof the die button 25 on which the washer is ultimately supported. Inother words, the metal washer contacts the side of the second component23 remote from the component 21 and is clamped firmly there under theaction of the spring-loaded hold-down member 43. In this way the firstcomponent 21 and the second component 23 are firmly clamped between theplate 13 and the metal washer. The metal washer acts as a loaddistributor with organic sheet parts so that the high riveting forcesare uniformly taken up without damaging the organic sheet part. When ametal washer is provided the metallic material of the metal washer islikewise driven by the ring-like projection 28 of the die button intothe undercuts 19, or the end face 16 of the pin 15 is, as describedabove—in accordance with the instructions in EP documentEP-A-2873473—embossed. In this way a form-fitted connection can beachieved also when a first organic sheet part 21 and a second organicsheet part 23 are present.

It is likewise conceivable that both the first component 21 and also thesecond component 23 are formed as metallic sheet metal parts. In thiscase a further metal washer is not necessary because the material of thesheet metal part itself has a corresponding flow characteristic.

Ultimately it should be brought out that a spring-loaded hold-downmember 43 is not absolutely essential when using the auxiliary joiningpart 11 in accordance with the invention because the forces which arerequired in order to break the position of intended fracture 17 likewiseexert a clamping force on the plate 13, the components 21 and 23 and ona washer received in the die button (as likewise described inEP-A-2873473) and it is possible that the friction forces exerted by theplunger on the plate during the piercing of the components is sufficientin order to avoid fraying out of any organic sheet parts that arepresent.

The auxiliary joining parts can also consist of all materials which arecustomary for punched rivets.

Some further examples of the invention will now be described and in thisfurther description parts which have the same design or function aspreviously described parts are provided with the same reference numeralsand it will be understood that the previous description likewise appliesto the further examples, providing the same reference numerals are usedand providing nothing is stated in contrary. For this reason, theprevious description will not be unnecessarily repeated.

Referring now to FIGS. 8A and 8B an arrangement is now shown in which awasher 59 is provided at the lower side of the stacked components 21, 23and fits into a recess 61 of a die button 25 and sits, in the open stateof the press or the like, on the ring nose or ring-like rejection 28provided there. As previously the ring-like projection surrounds anopening 63 of the die button through which and through the passage 25which follows the opening 63, the piercing slugs 27 can be disposed ofafter the closing of the press and the punching through of thecomponents 21, 23.

In this arrangement the lower component 23 is normally formed as anorganic sheet part. This is however not essential if, for example, thelower component consists of a soft sheet metal part, the connection ofwhich with the pin would be weak, then it could be appropriate to use ametal washer 59 which, on the one hand, enables a firm connection withthe lower end of the pin 15 and, on the other hand, exerts a loaddistributing function at the component 23.

FIG. 8B shows then the resulting component assembly 67 after closing ofthe press, after piercing of the components 21, 23 and the embossing ofthe upper end of the pin and of the material of a further washer 59 intothe undercut 19 at the lower end of the pin 15.

One can see from FIG. 8B that the further washer 59 has a ring-shapedimpression 69 which was generated by the ring-like projection 28 of thedie button 25, whereby the so displaced material of the washer 59 hasbrought about the form-fitted engagement with the undercut 19 or withits circular recesses 20. The embossed connection of the upper end ofthe pin 15 with the plate 13 is realized in precisely the same manner aspreviously described.

FIGS. 9A to 9D now show an alternative design of the auxiliary joiningpart 11 with premanufactured undercuts 19 at its two ends. Here, inanalogous manner to the embodiment of FIG. 8A, a further washer 59 isalso used which also sits here in a recess 61 of the die button 25 onthe ring-shape projection 28. The various phases of the attachmentprocess can be straightforwardly seen from the sequence of drawings 9Ato 9D with the aid of the previous description and reference numeralsthat are used. One can see from the FIGS. 10A and 10B, which show thecomponent assembly 67, that the attachment of the further washer 59 tothe lower end of the pin 15 of the auxiliary joining part 11 has takenplace in just the same manner as was described in connection with FIG.8A. The attachment of the plate 13 to the upper end of the pin 15however takes place here analogously to the attachment of the furtherwasher 59 with the lower end of the pin by the generation of a ringrecess or impression 69 in the plate around the upper end of the pin 15,whereby plate material is forced into the upper undercut 19. I.e. FIG.10B can, when turned through 180 degrees, be understood to represent theattachment of the plate to the adjacent end of the pin 15. Thissignifies that the outer plunger 73 of the setting head which surroundsthe inner plunger 71 has a ring nose 75 corresponding to the ring-likeprojection 28 in order to bring about the ring-shaped indentation 77 ofthe upper side of the plate 15. In this embodiment the inner plunger 73presses against the upper end face of the pin 15 in order to drive thisthrough the components. The corresponding tool of the press then firstpresses on the upper end face of the outer plunger 73 at the end of theclosing phase of the press after the movement of the inner plunger inlongitudinal direction L, at approximately the same point in time as thering-like projection 28 of the die button 25 serves for the indentationof the disc 59.

Instead of operating with a ring-like projection 28 and with a ring nose75 it could also be sufficient to operate with discrete projections ornoses which are arranged in a ring because, depending on the material,an adequate engagement material of the so embossed part could beachieved, be it of the further washer 59 or of the plate 13 into therespective undercuts 19.

A particularly preferred embodiment of the inner plunger 73 and of theouter plunger 71 which are used for a discrete embossing of the plate 13at three points is shown in FIGS. 11 and 12 . The outer plunger 71 has acylindrical body 79 with three flats 81 which serve for the guidance ofthe body within the setting head 41 at the correct angle around thecentral longitudinal axis L. The outer plunger 71 has an inner passage83 directed in the longitudinal direction L with an approximatelycloverleaf-like cross-section, the individual “leaves” of which arematched in shape to three tongues 87 of the inner plunger 73 and receivethese in a mutually displaceable manner. The outer plunger 71 has at itsupper end a cylindrical collar 89 which restricts the position of theouter plunger 71 in the setting head 41 or in the corresponding tool ofthe press. The inner plunger 73 likewise has a collar 91 at its upperend which restricts the displacement part of the inner plunger 73 withinthe outer plunger 71 in the longitudinal direction L in that the collar91 contacts the upper side of the collar 89 at the end of thedisplacement. One sees from FIG. 11 that the inner plunger has a centralopening 93 the base of which as shown in FIGS. 13A to 13D is inengagement with or presses against the upper end face of the pin 15 ofthe auxiliary joining part. One can see further that the free lower ends95 of the tongues 85 merge via a dish 96 into the central recess 93. Theprecise form can be seen from FIG. 11 . It should be mentioned that theouter plunger 71 has a non-visible cylindrical bore above thecloverleaf-like passage 83 in which the cylindrical portion 97 of theinner plunger is displaceable. Furthermore, a recess 99 of ring-shape inplan view is evident in FIG. 12 which receives the plate 13 in a mannerflush with the lower end face of the outer plunger 71 as can be seenfrom the FIGS. 13A to 13D. The base of the recess 93 is set back by thesame amount as the upper end of the pin 15 projects beyond the plate 13in the installed state.

FIGS. 13A to 13D now shows various phases of the attachment of anauxiliary joining part 11 with undercuts at the upper and lower ends ofthe pin 15 by means of a setting head 41 which is equipped with theinner plunger 73 and the outer plunger 71 of the FIGS. 11 and 12 . Therepresentations of the setting head 41 in FIGS. 13A to 13D have arisenfrom a CAD drawing and are somewhat misleading unless one takes accountof the description of FIGS. 11 and 12 and in addition recognizes thatFIGS. 13A to 13D only show the inter-engaging lower parts of the outerplunger 71 and of the inner plunger 73, where the three tongues 87 aredisplaceably guided within the cloverleaf-like passage 83, i.e.significantly below a cylindrical region 97 of the inner plunger 73. Theouter plunger 71 is to be understood here as the hold-down member whichcan be seen from the drawings of FIGS. 13A to 13D.

If one now considers the sectional drawing of FIG. 13A then one can seethat the outer plunger in the left-hand side of the drawing directlylies against the pin 15 of the auxiliary joining part, i.e. the sectionplane corresponds to the plane S-S in FIG. 12 . To the right of pin 15of the auxiliary joining part 11 there is a free space 101 shown withvertical lines. This free space is a section on the section plane S-S ofFIG. 12 through a “leaf” 85 of the cloverleaf-like passage 83 of theouter plunger. The vertical lines arise from the CAD drawing andrepresent lines at radii of the so-called leaf. Above this free space101 one can see a tongue 87 of the inner plunger 73. The section shownthrough the inner plunger 73 corresponds to the section plane T-T inFIG. 11 .

One can see from FIG. 13A two schematically illustrated coil springs 57which bias the outer plunger 71 downwardly so that, in the initialclosing process of the press, i.e. in the state of FIG. 13B, the outerplunger 71 presses the two components 21, 23 against one another withspring force and against the ring-like projection or ring nose 28 of thedie button 25. The spring force determines the lever of the preloadforce. As a rule, a plurality of springs are arranged around the centrallongitudinal axis L. They could also be replaced by hydraulic orpneumatic preload springs.

The die button 25 is, in this example, also made in two parts with anouter sprung cylinder 26 and an inner fixed cylinder 35 with a ring-likeprojection or ring nose 28. The outer cylinder 26 cooperates with thehold-down member 43 in order to preload the components under springpressure. In the closed position of the press as shown in FIGS. 13C and13D the outer cylinder moves downwardly and the ring nose 28 which nowprojects above the upper end face of the outer cylinder 26 generates aring recess in the lower component, whereby sheet material of the lowercomponent 23 flows into the lower circular recesses 20 of the pin 15 andleads to a form-fitted connection.

In a further closing phase of the press which is finished in FIG. 13Dthe inner plunger has been downwardly pressed by the press. The pin 15is separated at the position of intended fracture of plate 13 andpunches through the two components 21, 23 and generates the punch slugs27. At the end of this closing movement the three arms 103 of the dishof the inner plunger 73 scrape material away from the periphery of thepin 15 at three positions such as 105 and this material forms threeraised portions 107 at the upper side of the plate 13 and displacesmoreover the material of the plate 13 into the circular recesses 20 ofthe pin 15. The parts of the arms 103 of the dish 96 radially outside ofthe pin 15 bound the shape of the raised portions 107, which consist ofthe scraped away material, and ensure that the compressive stress in theplate 13 causes the plate material to flow into the ring recesses 20.

The free ends of the tongues 87 press at the upper side of the plate 13which is bounded on all sides and thus can only deform in the mannerdescribed. One can see at the position 105 that a corner region of thepin 15 has been pressed in. The other two positions 105 cannot be seenin the drawings of FIGS. 13C and 13D because they lie outside of thesection plane. They are, however, evident in FIG. 14B. FIG. 13D nowshows the finished state after the piercing slugs 27 have fallen awayprior to the opening of the press. The finished component assembly isshown in section in FIG. 14A and in a corresponding perspectiveillustration from above in FIG. 14D.

In the example of FIGS. 13A to 13D and FIGS. 14A and 14B the lowercomponent is a metallic component which is why one is not operating witha separate washer here. The upper component 21 can either be an organiccomponent or a metallic sheet metal part.

If the lower component 23 is an organic component then one can operatewith a washer in die button 25 in analogy to the illustrations of FIGS.9A to 9D, 10A and 10B.

Although in the illustration of FIGS. 13A and 13D and 14A and 14B thepin 15 of the auxiliary joining part 11 is provided with circularrecesses 20 at both ends threads can be used instead of circularrecesses. This also applies to all other embodiments with circularrecesses 20. It has been found that even if one dispenses with ringrecesses or any other form of undercut at the top end of the pin 15,i.e. operates with a purely cylindrical pin, that the raised portions ofmaterial or lugs 107 are sufficient to achieve a particularly firmconnection or riveted joint.

Finally, reference is made to FIGS. 15A to 15C. here a differentembodiment of an auxiliary joining part 11 is shown in which thecircular recesses 20 are provided at the pin 15 at the top whereas nocircular recesses are provided adjacent to the position of intendedfracture 17 and to the plate 13. The auxiliary joining part according toFIGS. 15A to 15C can be processed with a setting head analogous to thatshown in FIGS. 13A to 13D.

The die button must however be so designed that the lower, recess-free,end of the pin is deformed solely by a ring-like embossing, or byembossing at local positions, so that the embossed material comes to liebelow the lower component 23, if this is a metallic sheet metal part, orcomes to lie beneath a washer if the lower component 23 is an organiccomponent. This could take place in such a way that the die button 25 isdesigned as a reversed version of the setting head 41 of FIGS. 13A to13D. The extent of the deviation downwardly of the outer cylinder 26relative to the inner cylinder 35 of the die button could theoreticallybe made substantially smaller than the stroke of the inner plunger 73 ofthe setting head 41 relative to the outer plunger 71 since the diebutton now only has to emboss the lower end of the pin 15 and does nothave to serve for the punching through of the components 21, 23.However, it is necessary for the die button to be designed such that thepunched slugs 27 can be disposed of through the die button prior to theembossing of the lower end of the pin. To achieve this it isappropriate, in accordance with the invention, to increase the stroke ofthe inner cylinder 35 of the die button to permit the creation of atransverse passage extending from the bore of the outer cylinder 26 ofthe die button through the side wall of the outer cylinder 26 while theinner cylinder 35 is in a lowered position. In addition the bore of theouter cylinder needs to be large enough to allow free passage of theslugs down to and through the transverse bore. Since the inner cylinderhas to emboss the lower end of the pin 15 it needs to have an innerdiameter smaller than that of the pin 15 and an outer diameter such thatit can be adequately guided within the outer cylinder 26.

It is also conceivable to use an auxiliary joining part 11 with a pin 15without any undercuts, circular recesses or threads if the setting headis designed as described in the FIGS. 13A to 13D and if the die buttonis designed as outlined in the previous paragraph. Other designs of thesetting head 41 and the die button 25 can also be considered when acylindrical pin is used so long as it is designed in order to form aform-fitted connection with the plate 13 or with a further washer orwith the lowermost component.

When designations such as top and bottom or similar geometricexpressions are used in this application then this is always related tothe orientation of the drawings and should not be understood as ageometric restriction.

REFERENCE NUMERAL LIST

-   11 auxiliary joining part-   13 plate-   15 pin-   16 end face-   17 position of intended fracture-   18 recess-   19 undercut-   20 circular recesses at the pin 15-   21 first component-   23 second component-   25 die button-   26 outer cylinder of the die button 25-   27 slug-   28 ring-like projection-   29 deformation/embossing-   30 solder joint-   31 brazed joint-   32 welded positions-   33 adhesive joint-   34 force transmitting and form-fitted connection-   35 inner cylinder of the die button 25-   41 setting head-   43 hold-down member-   45 holder-   47 ring-   49 plunger-   51 upper platen/tool of the press-   53 intermediate platen/tool of the press-   55 lower platen/tool of the press-   57 spring-   59 washer-   61 recess of the die button 25-   63 opening of the die button 25-   65 passage of the die button 25-   67 component assembly-   69 indentation-   71 outer plunger of the setting head 41, hold down member-   73 inner plunger of the setting head 41-   75 ring nose of the outer plunger 71-   77 indentation of the plate 13-   79 cylindrical body of the outer plunger 71-   81 flats of the cylindrical body 79-   83 cloverleaf-like passage of the outer plunger-   85 leaves of the cloverleaf-like passage of the outer plunger 71-   87 tongues of the inner plunger 73-   89 collar of the outer plunger 71-   91 collar of the inner plunger 73-   93 recess of the inner plunger 73-   95 free ends of the tongues 87-   96 dish-   97 cylindrical sections of the inner plunger-   99 end recess of the outer plunger-   101 free space-   103 arms of the dish 96-   105 position, pressed-in corner region of the pin 15-   107 raised portions at the upper side of the plate 13, lugs-   B direction of movement of the pin-   K action of force-   L central longitudinal axis-   S-S sectional plane-   T-T sectional plane

The invention claimed is:
 1. A component assembly comprising: anauxiliary joining part including a solid pin (15) having a front endinitially fixed to a plate (13) and a tail end initially being remotefrom the plate (13), with a position of intended fracture (17) presentbetween the plate (13) and the front end of the solid pin (15), a firstcomponent (21); and a second component (23), the first component (21),the second component (23) and the plate (13) being in a stackedarrangement, such that the plate (13) contacts the first component (21),wherein at least one of the front end of the solid pin (15) is fracturedand separated from the plate (13) at the position of intended fracture(17) and pressed through the second component (23), the second component(23) and a washer (59) which is optionally provided at the secondcomponent (23) at a side of the second component (23) remote from thefirst component (21), is deformed thus providing a form-lockedconnection between the front end of the solid pin (15) and the secondcomponent (23) and the solid pin (15) and the washer (59) if provided,and at least one of the plate (13) and the tail end of the solid pin(15) is deformed thus providing a form-fitted connection between theplate (13) and the tail end of the solid pin (15).
 2. The componentassembly of claim 1, wherein the pin (15) is solid along a centrallongitudinal axis (L).
 3. The component assembly of claim 1, wherein theform-fitted connection between the plate (13) and the tail end of thepin (15) fixes separated material of the pin (15) and the plate (13)together.
 4. The component assembly of claim 1, wherein the pin (15) hasat least one annular undercut (19) adjacent the front end of the pin(15).
 5. The component assembly of claim 4, wherein the form-lockedconnection between the pin (15) and the second component (23) is formedby material of the second component (23) extending into the at least oneannular undercut (19).
 6. The component assembly of claim 5, wherein theat least one annular undercut (19) includes a plurality of annularundercuts (19).
 7. The component assembly of claim 4, wherein the pin(15) has at least one annular undercut (19) adjacent the tail end of thepin (15).
 8. The component assembly of claim 1, wherein the front end ofthe pin (15) which is fractured and separated from the plate (13) isclosed.